AT404986B - HEAT EXCHANGER - Google Patents

Description

AT 404 986 B

The invention relates to a heat exchanger according to the preamble of claim 1.

In known heat exchangers of this type, flat fins are connected to the tube, usually by means of soldered connections. In order to increase the heat exchanger area, it is only possible to either reduce the distances between the individual fins or to increase the length of the tube or to increase the size of the fins. The first-mentioned possibility soon reaches physical limits which are caused by the increase in flow resistance with a decreasing distance between the fins.

An extension of the tube or an enlargement of the fins leads to an enlargement of the heat exchanger, which should be avoided as far as possible. The aim of the invention is to avoid these disadvantages and to propose a heat exchanger of the type mentioned at the outset, which is distinguished by a compact structure with the largest possible heat exchanger surface.

According to the invention, this is achieved in a heat exchanger of the type mentioned at the outset by the characterizing features of claim 1. 15 The features proposed make it possible to increase the heat exchanger area compared to heat exchangers of the same type and size with flat fins, without the outer dimensions of the heat exchanger itself being increased thereby.

The features of claim 2 have the advantage that the troughs can be aligned in the flow direction of the fuel gases. This results in a relatively low flow resistance for the fuel gases.

The features of claim 3 give the advantage of a very rigid connection of the fins to the tube.

The features of claim 4 allow a very good heat transfer from the fins to the pipe and thus to the water flowing through it. 25 The features of claims 5 and 6 allow a very extensive use of the available space and an extremely compact structure of a heat exchanger. Only very small gaps remain between the fins of different pipes or pipe sections of the heat exchanger.

Due to the features of claim 7, when the fuel gases flow through the individual lamellae, there is a greater swirl which is caused by the corrugation of the lamellae. 30 This leads to a very intensive heat exchange between the fuel gases and the fins and thus also with the water flowing through the pipe.

The features of claim 8 allow easy assembly of the fins on the tube of the heat exchanger. It is only necessary to widen the slit of the fins, which makes it easier to push the fins onto the pipe. 35 The slats can be placed particularly easily on a tube if a tool according to claim 9 is used.

A particularly high level of corrosion resistance can be achieved by the features of claim 10.

Due to the features of claim 11, the path of the water through the heat exchanger 40 can be extended considerably without the pipe having to be extended. The cooler water can be guided in the inner tube and preheated and further heated in the annular space between the two tubes.

The features of claim 12 also result in the advantage of very high security against corrosion. 45 Due to the features of claim 14 there is also an extension of the path of the water in the heat exchanger, this solution being characterized by a particular simplicity.

A particularly simple heat exchanger results from the features of claim 15. Such a heat exchanger can be produced simply by internal high-pressure forming of the tube. This results in corresponding bulges, through which the surface of the tube per unit length is increased accordingly.

A particularly extensive enlargement of the surface of a tube per unit length results from the features of claim 16. Such a heat exchanger can be produced simply by deforming a tube, preferably made of stainless steel, preferably by means of internal high-pressure forming, and then compressing the bulges . With such a 55 heat exchanger there is also the advantage that no soldered connections are required which are problematic in terms of corrosion resistance.

The features of claim 17 or 18 result in a high degree of corrosion resistance, and the stainless steel tube can be very thin-walled. The result of this is the stainless steel tube 2

AT 404 986 B inserted copper pipe or the copper layer a very good distribution of the heat over the circumference of the pipe and thus a uniform heating of the water flowing in this. This also prevents local overheating, which can lead to boiling noises.

The invention will now be explained in more detail with reference to the drawing.

Show:

1 schematically shows a heat exchanger according to the invention,

2 and 3 different shapes of slats,

4 shows a heat exchanger with fins according to Hg. 2,

5 to 7 different attachments of fins of a heat exchanger according to the invention,

Ed. 8 to 13 further embodiments and fastenings of slats,

14 and 15 a further embodiment of a lamella,

Ed. 16 and 17 schematically show a tool for placing fins according to Ed. 14 on a pipe, Ed. 18 a further embodiment of a heat exchanger according to the invention,

19 to 21 cross sections through different embodiments of heat exchangers according to Ed. 18,

22 to 24 further embodiments of a heat exchanger,

25 shows a horizontal section through the heat exchanger according to FIG. 24,

26 and 27 heat exchangers, which are made from a deformed tube, and Hg. 28 another embodiment of a heat exchanger.

The same reference symbols mean the same details in all editions.

1 shows a lintel burner 1 arranged in a heating shaft 3, which is connected to the heating shaft 3 via a holder 2. This tumble burner acts on a heat exchanger which is formed from a plurality of tubes 4, preferably made of stainless steel, on which fins 5 are pushed and connected to tube 4. 5 spaces remain between the lamellae. The lamellae 5 have corrugations 7 that run along chords and are oriented parallel to one another.

Hg. 1 shows circular slats 5, whereas Hg. 2 and 3 slats 5 'with essentially triangular or slats 5 " show with a substantially rectangular shape. The slats 5 ', 5 " provided with corrugations 7.

4 shows a further embodiment of a heat exchanger, fins 5 'being provided. This enables a very dense arrangement of the tubes 4 together with fins 5 ', with only small gaps 9 remaining between the fins 5' arranged on different tubes 4 '.

5 shows a section of a tube 4, preferably made of stainless steel, with fins 5, which are provided with a foot 8 which bears against the tube 4.

In the embodiment according to Hg. 6, the feet 8 'of the slats are angled in a U-shape and soldered to the tube 4, which is preferably made of stainless steel.

In the embodiment according to FIG. 7, the fins 5 are soldered directly to the tube 4.

Fig. 8 shows a lamella 51 with a circular shape, which is provided with concentrically arranged corrugations 7 '. The lamella is provided with a foot 8 which, as can be seen from Hg. 9, bears against the tube 4.

The lamella 51 'according to FIG. 10 is also provided with concentric corrugations 7' and has a U-shaped angled foot 8 '.

In the embodiment according to FIGS. 12 and 13, a lamella 51 " no foot on and is soldered directly to the tube 4, the lamella 51 " has concentric corrugations 7 '.

In the embodiment according to FIGS. 14 and 15, a lamella 52 has a slot 10 which extends from the outer circumference to the opening for receiving the tube 4. Furthermore, the lamella 52 has a corrugation 7 running along tendons. As can be seen from Hg. 15, the fins 52 are soldered directly to the tube 4. However, foot shapes according to foot 8 or foot 8 'are also possible.

A heat exchanger provided with such fins 52 can be produced very easily with the tool shown in FIGS. 16 and 17. This tool has a holder 11, which is provided with a number of compartments 12 for receiving lamellae 52, the compartments 12 simultaneously defining the mutual distance of the lamellae 52 from one another.

The walls 13 of the compartments 12 of the holder 11 are provided with a recess 14 which expose the central bore 15 of the slats 52.

By aligning the slots 10 of the fins 52 and applying a spreading tool 16 with a round shape or wedge shape on the outer edges of the slots 10, the fins 52 can be expanded and a tube 4 made of stainless steel, for example, or a copper tube can easily be inserted into the bores 15 of the fins 52 can be inserted. 3rd

Claims (18)

AT 404 986 B After the wedge 16 has been removed and the tube 4 equipped with the fins 52 has been lifted out, the fins 52 being pressed against the tube 4, the fins 52 can be soldered to the tube 4. 18 shows a heat exchanger arranged in a heating shaft 3, which is formed by a ceramic tube 4 ′ equipped with fins 53. the fins 53 being formed in one piece with the ceramic tube 4 '. 19 to 21 show different embodiments of fins formed in one piece with a ceramic tube 4 '. The slats 53 are circular and the slats 53 'are essentially triangular, whereas the slats 53 " are essentially square. The slats 53. 53 ', 53 " just be trained. In the embodiment according to FIG. 22, an inner tube 17 is arranged coaxially in the tube 4 provided with fins 5, which may also be flat, which is usually made of stainless steel. In this case, as can be seen from FIG. 22a, spacers 18 are provided offset, for example, by 120 *. The open end of the inner tube 17 ends in front of a closed end of the tube 4. This results in an opposite flow in the inner tube 17 and in the annular space 19 between the inner tube 17 and the tube 4. The embodiment according to FIGS. 23, 23a differs from that 22, 22a only in that a tube 4 'made of ceramic and formed in one piece with fins 53 is provided, in which an inner tube 17 is held concentrically. The slats 53 can be designed with or without corrugations. In the embodiment according to FIGS. 24 and 25, the tubes 4 are divided by diametrically extending webs 20, the webs 20 ending in front of the closed ends of the tubes 4 and the water therefore in one half of the tubes 4 in one direction and in the other half can flow in the opposite direction. The tubes 4 are equipped with fins 52 which are provided with slots 10. As can be seen from FIG. 25, the individual tubes 4 are connected to one another via overflow regions 21, the overflow regions 21 being separated from one another by the webs 20. FIG. 26 shows a heat exchanger which is passed through a pipe 4 " or a copper tube is formed, which is provided with bulges 54 produced, for example, by hydroforming. FIG. 27 shows a heat exchanger which essentially corresponds to that according to FIG. 26. However, the bulges 54 'are pressed flat in the axial direction. There are bulges 54 ', which essentially correspond to lamellae, but in one piece with the tube 4 " or a copper tube are formed. In the embodiment according to FIG. 28, for example a stainless steel tube 41 is provided, which is provided with fins 5. A copper tube 42, for example, is pressed into this thin-walled stainless steel tube 41 and / or is integrally connected. A type of composite pipe is thereby formed, in which, for example, a stainless steel pipe 41 provides corrosion protection and, for example, a copper pipe 42 causes an even distribution of the heat. 1. Heat exchanger with at least one tube (4) and projecting therefrom, essentially thin-walled elements, characterized in that the tube (4) in a known manner fins (5, 5 ', 5 ”, 51, 51', 51 ") protrude, which have corrugations (7). 2. Heat exchanger according to claim 1, characterized in that the troughs of the corrugations (7) run parallel to each other (Fig. 1 to 4.14). 3. Heat exchanger according to claim 1 or 2, characterized in that each fin (5) on a tube (4) connected to the base (8, 8 ') is held (Fig. 5, 6, 9, 11). 4. Heat exchanger according to claim 1 or 2, characterized in that the fins (5) are soldered directly to the tube (4) (Fig. 7.13). 5. Heat exchanger according to claim 1 or 2, characterized in that the fins (5 ') are substantially triangular (Fig. 2). 4 ΑΤ 404 986 Β 6. Heat exchanger according to claim 1 or 2, characterized in that the fins (5 ") are substantially rectangular, in particular square, (Fig. 3). 7. Heat exchanger according to claim 1, characterized in that the corrugation (7 *) of the fins (51) has concentrically arranged troughs (Fig. 8, 10, 12). 8. Heat exchanger according to one of claims 1 to 7, characterized in that the fins (52) have a slot (10) extending from their outer edge to their receiving the tube (4) provided central bore (10) (Fig. 14) . 9. Heat exchanger with at least one tube (4 ') and projecting therefrom, essentially thin-walled elements, characterized in that the tube (4') is made in one piece with fins (53) made of ceramic (Fig. 18). 10. Heat exchanger with at least one tube (4) and projecting therefrom, essentially thin-walled elements, characterized in that in the tube, preferably made of stainless steel (4), a further inner tube (17) is provided which is held coaxially by means of spacers (18) (Figs. 22, 22a). 11. Heat exchanger with at least one tube (4 ') and projecting therefrom, essentially thin-walled elements, characterized in that in the one-piece with fins (53) made of ceramic tube (4') by means of an inner tube made of sheet metal (17) Spacer (18) is held concentrically (Fig. 23, 23a). 12. Heat exchanger according to claim 11, characterized in that the fins (53) have corrugations (7, 7 '). 13. Heat exchanger with at least one tube (4) and projecting therefrom, essentially thin-walled elements, characterized in that the tube (4) is divided by an essentially diametrically extending web (20) protruding into it, which extends to close a closed end of the tube (4) extends (Fig. 24, 25). 14. Heat exchanger with at least one tube (4 "), characterized in that the tube (4 ") made of copper is provided with corrugations (54) (Fig. 26). 15. Heat exchanger with at least one tube (4 ") and essentially thin-walled elements projecting therefrom, characterized in that the tube (4 ") made of copper is provided or shaped with flattened bulges (54 ') (Fig. 27) . 16. Heat exchanger with at least one tube (41) and protruding therefrom, essentially thin-walled elements, characterized in that a tube (42), for example made of copper, is inserted into the tube (41) made, for example, of stainless steel, wherein in essentially a press fit is provided (Fig. 28). 17. Heat exchanger with at least one tube (41) and projecting therefrom, essentially thin-walled elements, characterized in that the inside of the tube (41), for example made of stainless steel, is integrally connected to a copper layer. 18. Tool for producing a heat exchanger according to claim 8, characterized in that a holder (11) for receiving the individual fins (52) is provided, the compartments (12) for receiving the fins (52), the walls of the compartments (12) to expose the central bores (15) of the fins (52) receiving the tube (4) and have recesses (14) and a wedge (16) which can be replaced in the outer edge of the slots (10) to spread the fins ( 52) is provided during the insertion of the tube (4) (Fig. 16, 17). Including 14 sheets of drawings 5